5.1 Introduction Chapter 5 The Second aw of Thermodynamics The second law of thermodynamics states that processes occur in a certain direction, not in just any direction. Physical processes in nature can proceed toward equilibrium spontaneously: Water flows down a waterfall. Gases expand from a high pressure to a low pressure. Heat flows from a high temperature to a low temperature. Once it has taken place, a spontaneous process can be reversed, but it will not reverse itself spontaneously. Some external inputs, energy, must be expended to reverse the process. As it falls down the waterfall, water can be collected in a water wheel, cause a shaft to rotate, coil a rope onto the shaft, and lift a weight. So the energy of the falling water is captured as potential energy increase in the weight, and the first law of thermodynamics is satisfied. However, there are losses associated with this process (friction). Allowing the weight to fall, causing the shaft to rotate in the opposite direction, will not pump all of the water back up the waterfall. Spontaneous processes can proceed only in a particular direction. The first law of thermodynamics gives no information about direction; it states only that when one form of energy is converted into another, identical quantities of energy are involved regardless of the feasibility of the process. We know by experience that heat flows spontaneously from a high temperature to a low temperature. But heat flowing from a low temperature to a higher temperature with no expenditure of energy to cause the process to take place would not violate the first law. The first law is concerned with the conversion of energy from one form to another. Joule's experiments showed that energy in the form of heat could not be completely converted into work; however, work energy can be completely converted into heat energy. Evidently heat and work are not completely interchangeable forms of energy. Furthermore, when energy is transferred from one form to another, there is often a degradation of the supplied energy into a less useful form. We shall see that it is the second law of thermodynamics that controls the direction processes may Compiled by Yidnekachew M. Page 1 of 23
take and how much heat is converted into work. A process will not occur unless it satisfies both the first and the second laws of thermodynamics. 5.2 Some Definitions To express the second law in a workable form, we need the following definitions. Heat (thermal) reservoir A heat reservoir is a sufficiently large system in stable equilibrium to which and from which finite amounts of heat can be transferred without any change in its temperature. A high temperature heat reservoir from which heat is transferred is sometimes called a heat source. A low temperature heat reservoir to which heat is transferred is sometimes called a heat sink. Work reservoir A work reservoir is a sufficiently large system in stable equilibrium to which and from which finite amounts of work can be transferred adiabatically without any change in its pressure. Thermodynamic cycle A system has completed a thermodynamic cycle when the system undergoes a series of processes and then returns to its original state, so that the properties of the system at the end of the cycle are the same as at its beginning. Thus, for whole numbers of cycles P P, T T, u u, v v, etc. 5.3 Heat Engine f i f i f i f i Work can easily be converted to other forms of energy, but converting other forms of energy to work is not that easy. The mechanical work done by the shaft shown in Figure (5.1), for example, is first converted to the internal energy of the water. This energy may then leave the water as heat. We know from experience that any attempt to reverse this process will fail. That is, transferring heat to the water does not cause the shaft to rotate. Compiled by Yidnekachew M. Page 2 of 23
Figure 5.1 Work can always be converted to heat directly and completely, but the reverse is not true. From this and other observations, we conclude that work can be converted to heat directly and completely, but converting heat to work requires the use of some special devices. These devices are called heat engines. A heat engine is a thermodynamic system operating in a thermodynamic cycle to which net heat is transferred and from which net work is delivered. The system, or working fluid, undergoes a series of processes that constitute the heat engine cycle. Heat engines differ considerably from one another, but all can be characterized by the following They receive heat from a high-temperature source (solar energy, oil furnace, nuclear reactor, etc.). They convert part of this heat to work (usually in the form of a rotating shaft). They reject the remaining waste heat to a low-temperature sink (the atmosphere, rivers, etc.). They operate on a cycle. Compiled by Yidnekachew M. Page 3 of 23
Figure 5.2 Part of the heat received by a heat engine is converted to work, while the rest is rejected to a sink. Engines that involve internal combustion such as gas turbines and car engines fall into this category. The work-producing device that best fits into the definition of a heat engine is the steam power plant, which is an external-combustion engine. That is, combustion takes place outside the engine, and the thermal energy released during this process is transferred to the steam as heat. Figure (5.2) illustrates a schematic diagram of steam power plant as a heat engine operating in a thermodynamic cycle. The various quantities shown on this figure are as follows: Qin = amount of heat supplied to steam in boiler from a high-temperature source (furnace) Qout= amount of heat rejected from steam in condenser to a low-temperature sink (the atmosphere, a river, etc.) Wout = amount of work delivered by steam as it expands in turbine Win = amount of work required to compress water to boiler pressure Compiled by Yidnekachew M. Page 4 of 23
Figure 5.3 Components of a simple vapor power plant. Using the first law of thermodynamics for the system Q W U net, in net, out 0 (Cyclic) W Q net, out net, in W Q Q net, out in out If we want to compare the output against the input, we introduce Thermal Efficiency for the cycle. The thermal efficiency is the index of performance of a work-producing device or a heat engine and is defined by the ratio of the net work output (the desired result) to the heat input (the costs to obtain the desired result). Desired Result Net work output Termal efficency = Required Input Total heat input For a heat engine the desired result is the net work done and the input is the heat supplied to make the cycle operate. Termal efficency Net work output Total heat input Compiled by Yidnekachew M. Page 5 of 23
The thermal efficiency is always less than 1 or less than 100 percent. th W Q Q Q Q net, out in out in in Q th Q 1 out Cyclic devices such as heat engines, refrigerators, and heat pumps often operate between a hightemperature reservoir at temperature TH and a low temperature reservoir at temperature T. To bring uniformity to the treatment of heat engines, refrigerators, and heat pumps, we define these two quantities: QH = magnitude of heat transfer between the cyclic device and the high-temperature medium at temperature TH Q = magnitude of heat transfer between the cyclic device and the low-temperature medium at temperature T Then the net work output and thermal efficiency relations for any heat engine (shown in Fig 5.4) can also be expressed as W Q Q (5.1) net, out H W net, out th or th 1 QH QH in Q (5.2) Figure 5.4 Schematic of a heat engine. Compiled by Yidnekachew M. Page 6 of 23
5.4 Refrigerators and Heat Pumps We all know from experience that heat is transferred in the direction of decreasing temperature, that is, from high-temperature mediums to low-temperature ones. This heat transfer process occurs in nature without requiring any devices. The reverse process, however, cannot occur by itself. The transfer of heat from a low-temperature medium to a high-temperature one requires special devices called refrigerators. Refrigerators, like heat engines, are cyclic devices. The working fluid used in the refrigeration cycle is called a refrigerant. The most frequently used refrigeration cycle is the vaporcompression refrigeration cycle, which involves four main components: a compressor, a condenser, an expansion valve, and an evaporator, as shown in Figure (5.5). Figure 5.5 Basic components of a refrigeration system and typical operating conditions. The refrigerant enters the compressor as a vapor and is compressed to the condenser pressure. It leaves the compressor at a relatively high temperature and cools down and condenses as it flows through the coils of the condenser by rejecting heat to the surrounding medium. It then enters a capillary tube where its pressure and temperature drop drastically due to the throttling effect. The low-temperature refrigerant then enters the evaporator, where it evaporates by absorbing heat from the refrigerated space. The cycle is completed as the refrigerant leaves the evaporator and reenters the compressor. Compiled by Yidnekachew M. Page 7 of 23
In a household refrigerator, the freezer compartment where heat is absorbed by the refrigerant serves as the evaporator, and the coils usually behind the refrigerator where heat is dissipated to the kitchen air serve as the condenser. A refrigerator is shown schematically in Figure (5.6). Here Q is the magnitude of the heat removed from the refrigerated space at temperature T, QH is the magnitude of the heat rejected to the warm environment at temperature TH, and Wnet,in is the net work input to the refrigerator. As discussed before, Q and QH represent magnitudes and thus are positive quantities. Figure 5.6 The objective of a refrigerator is to remove Q from the cooled space. Another device that transfers heat from a low-temperature medium to a high-temperature one is the heat pump, shown schematically in Figure (5.7). Refrigerators and heat pumps operate on the same cycle but differ in their objectives. The objective of a refrigerator is to maintain the refrigerated space at a low temperature by removing heat from it. Discharging this heat to a highertemperature medium is merely a necessary part of the operation, not the purpose. The objective of a heat pump, however, is to maintain a heated space at a high temperature. This is accomplished by absorbing heat from a low-temperature source, such as well water or cold outside air in winter, and supplying this heat to the high-temperature medium such as a house. Compiled by Yidnekachew M. Page 8 of 23
Figure 5.7 The objective of a heat pump is to supply heat QH into the warmer space. The index of performance of a refrigerator or heat pump is expressed in terms of the coefficient of performance, COP, the ratio of desired result to input. This measure of performance may be larger than 1, and we want the COP to be as large as possible. For the refrigerator the desired result is the heat supplied at the low temperature and the input is the net work into the device to make the cycle operate. Desired Result COP = Required Input (5.3) COP R Q W (5.4) net, in Now apply the first law to the cyclic refrigerator. ( Q Q ) (0 W ) U 0 (5.5) H in cycle W W Q Q (5.6) in net, in H Compiled by Yidnekachew M. Page 9 of 23
and the coefficient of performance becomes COP R Q Q Q H (5.7) For the device acting like a heat pump, the primary function of the device is the transfer of heat to the high-temperature system. The coefficient of performance for a heat pump is COP HP QH QH W Q Q net, in H (5.8) Note, under the same operating conditions the COPHP and COPR are related by COP HP COP 1 (5.9) R 5.5 Statements of the Second aw of thermodynamic The following two statements of the second law of thermodynamics are based on the definitions of the heat engines and heat pumps. Kelvin-Planck statement of the second law It is impossible for any device that operates on a cycle to receive heat from a single reservoir and produce a net amount of work. The Kelvin-Planck statement of the second law of thermodynamics states that no heat engine can produce a net amount of work while exchanging heat with a single reservoir only. That is, a heat engine must exchange heat with a low-temperature sink as well as a hightemperature source to keep operating. The Kelvin Planck statement can also be expressed as no heat engine can have a thermal efficiency of 100 percent, or as for a power plant to operate, the working fluid must exchange heat with the environment as well as the furnace. Compiled by Yidnekachew M. Page 10 of 23
Figure 5.8 Heat engine that violates the Kelvin-Planck statement of the second law Clausius statement of the second law The Clausius statement of the second law states that it is impossible to construct a device that operates in a cycle and produces no effect other than the transfer of heat from a lower-temperature body to a higher temperature body. Figure 5.9 A refrigerator that violates the Clausius statement of the second law. Compiled by Yidnekachew M. Page 11 of 23
Or energy from the surroundings in the form of work or heat has to be expended to force heat to flow from a low-temperature medium to a high temperature medium. Thus, the COP of a refrigerator or heat pump must be less than infinity. (COP < ) Consider the heat-engine-refrigerator combination shown in Fig. 5 10a, operating between the same two reservoirs. The heat engine is assumed to have, in violation of the Kelvin Planck statement, a thermal efficiency of 100 percent, and therefore it converts all the heat QH it receives to work W. This work is now supplied to a refrigerator that removes heat in the amount of Q from the low-temperature reservoir and rejects heat in the amount of Q+ QH to the high-temperature reservoir. During this process, the high-temperature reservoir receives a net amount of heat Q (the difference between Q+QH and QH). Thus, the combination of these two devices can be viewed as a refrigerator, as shown in Fig. 5-10b, that transfers heat in an amount of Q from a cooler body to a warmer one without requiring any input from outside. This is clearly a violation of the Clausius statement. Therefore, a violation of the Kelvin Planck statement results in the violation of the Clausius statement. Compiled by Yidnekachew M. Page 12 of 23
Figure 5.10 Proof that the violation of the Kelvin Planck statement leads to the violation of the Clausius statement. Perpetual-Motion Machines Any device that violates the first or second law of thermodynamics is called a perpetual-motion machine and despite numerous attempts, no perpetual-motion machine is known to have worked. A device that violates the first law of thermodynamics (by creating energy) is called a perpetualmotion machine of the first kind (PMM1), and a device that violates the second law of thermodynamics is called a perpetual-motion machine of the second kind (PMM2). Consider the steam power plant shown in Fig. 5-11. It is proposed to heat the steam by resistance heaters placed inside the boiler, instead of by the energy supplied from fossil or nuclear fuels. Part of the electricity generated by the plant is to be used to power the resistors as well as the pump. The rest of the electric energy is to be supplied to the electric network as the net work output. The inventor claims that once the system is started, this power plant will produce electricity indefinitely without requiring any energy input from the outside. Figure 5.11 A perpetual-motion machine that violates the first law of thermodynamics. Well, here is an invention that could solve the world s energy problem-f it works, of course. A careful examination of this invention reveals that the system enclosed by the shaded area is continuously supplying energy to the outside at a rate of, without receiving any energy. That is, this system is creating energy at a rate of, which is clearly a Compiled by Yidnekachew M. Page 13 of 23
violation of the first law. Therefore, this wonderful device is nothing more than a PMM1 and does not warrant any further consideration. 5.6 Reversible and Irreversible Processes The second law of thermodynamics states that no heat engine can have an efficiency of 100 percent. Then one may ask, what is the highest efficiency that a heat engine can possibly have? Before we can answer this question, we need to define an idealized process first, which is called the reversible process. The processes that were discussed at the beginning of this chapter occurred in a certain direction. Once having taken place, these processes cannot reverse themselves spontaneously and restore the system to its initial state. For this reason, they are classified as irreversible processes. Once a cup of hot coffee cools, it will not heat up by retrieving the heat it lost from the surroundings. If it could, the surroundings, as well as the system (coffee), would be restored to their original condition, and this would be a reversible process. A reversible process is defined as a process that can be reversed without leaving any trace on the surroundings. That is, both the system and the surroundings are returned to their initial states at the end of the reverse process. This is possible only if the net heat and net work exchange between the system and the surroundings is zero for the combined (original and reverse) process. Processes that are not reversible are called irreversible processes. Figure 5.12 Two familiar reversible processes. Reversible processes actually do not occur in nature. They are merely idealizations of actual processes. Reversible processes can be approximated by actual devices, but they can never be Compiled by Yidnekachew M. Page 14 of 23
achieved. That is, all the processes occurring in nature are irreversible. You may be wondering, then, why we are bothering with such fictitious processes. There are two reasons. First, they are easy to analyze, since a system passes through a series of equilibrium states during a reversible process; second, they serve as idealized models to which actual processes can be compared. Reversible processes can be viewed as theoretical limits for the corresponding irreversible ones. Some processes are more irreversible than others. We may never be able to have a reversible process, but we can certainly approach it. The more closely we approximate a reversible process, the more work delivered by a work-producing device or the less work required by a workconsuming device. Irreversibilities The factors that cause a process to be irreversible are called irreversibilities. They include friction, unrestrained expansion, mixing of two fluids, heat transfer across a finite temperature difference, electric resistance, inelastic deformation of solids, and chemical reactions. The presence of any of these effects renders a process irreversible. A reversible process involves none of these. Internally and Externally Reversible Processes A process is called internally reversible if no irreversibilities occur within the boundaries of the system during the process. During an internally reversible process, a system proceeds through a series of equilibrium states, and when the process is reversed, the system passes through exactly the same equilibrium states while returning to its initial state. That is, the paths of the forward and reverse processes coincide for an internally reversible process. The quasi-equilibrium process is an example of an internally reversible process. A process is called externally reversible if no irreversibilities occur outside the system boundaries during the process. Heat transfer between a reservoir and a system is an externally reversible process if the outer surface of the system is at the temperature of the reservoir. A process is called totally reversible, or simply reversible, if it involves no irreversibilities within the system or its surroundings (Fig. 6 35). A totally reversible process involves no heat transfer through a finite temperature difference, no nonquasi-equilibrium changes, and no friction or other dissipative effects. Compiled by Yidnekachew M. Page 15 of 23
Figure 5.13 A reversible process involves no internal and external irreversibilities. 5.7 The Carnot Cycle French military engineer Nicolas Sadi Carnot (1769-1832) was among the first to study the principles of the second law of thermodynamics. Carnot was the first to introduce the concept of cyclic operation and devised a reversible cycle that is composed of four reversible processes, two isothermal and two adiabatic. Reversible Isothermal Expansion (process 1-2, TH = constant). Initially (state 1), the temperature of the gas is TH and the cylinder head is in close contact with a source at temperature TH. The gas is allowed to expand slowly, doing work on the surroundings. As the gas expands, the temperature of the gas tends to decrease. But as soon as the temperature drops by an infinitesimal amount dt, some heat is transferred from the reservoir into the gas, raising the gas temperature to TH. Thus, the gas temperature is kept constant at TH. Since the temperature difference between the gas and the reservoir never exceeds a differential amount dt, this is a reversible heat transfer process. It continues until the piston reaches position 2. The amount of total heat transferred to the gas during this process is QH. Compiled by Yidnekachew M. Page 16 of 23
Reversible Adiabatic Expansion (process 2-3, temperature drops from TH to T). At state 2, the reservoir that was in contact with the cylinder head is removed and replaced by insulation so that the system becomes adiabatic. The gas continues to expand slowly, doing work on the surroundings until its temperature drops from TH to T (state 3). The piston is assumed to be frictionless and the process to be quasi-equilibrium, so the process is reversible as well as adiabatic. Reversible Isothermal Compression (process 3-4, T = constant). At state 3, the insulation at the cylinder head is removed, and the cylinder is brought into contact with a sink at temperature T. Now the piston is pushed inward by an external force, doing work on the gas. As the gas is compressed, its temperature tends to rise. But as soon as it rises by an infinitesimal amount dt, heat is transferred from the gas to the sink, causing the gas temperature to drop to T. Thus, the gas temperature remains constant at T. Since the temperature difference between the gas and the sink never exceeds a differential amount dt, this is a reversible heat transfer process. It continues until the piston reaches state 4. The amount of heat rejected from the gas during this process is Q. Reversible Adiabatic Compression (process 4-1, temperature rises from T to TH). State 4 is such that when the low-temperature reservoir is removed, the insulation is put back on the cylinder head, and the gas is compressed in a reversible manner, the gas returns to its initial state (state 1). The temperature rises from T to TH during this reversible adiabatic compression process, which completes the cycle. Compiled by Yidnekachew M. Page 17 of 23
Figure 5.14 Execution of the Carnot cycle in a closed system. The P-V diagram of this cycle is shown in Fig. 5.15. Remembering that on a P-V diagram the area under the process curve represents the boundary work for quasi-equilibrium (internally reversible) processes, we see that the area under curve 1-2-3 is the work done by the gas during the expansion part of the cycle, and the area under curve 3-4-1 is the work done on the gas during the compression part of the cycle. The area enclosed by the path of the cycle (area 1-2-3-4-1) is the difference between these two and represents the net work done during the cycle. Figure 5.15 P-V diagram of the Carnot cycle. You may have observed that the power cycle operates in the clockwise direction when plotted on a process diagram. The Carnot cycle may be reversed, in which it operates as a refrigerator. The refrigeration cycle operates in the counter clockwise direction. Compiled by Yidnekachew M. Page 18 of 23
Figure 5.16 P-V diagram of the reversed Carnot cycle. 5.8 Carnot Principles The second law of thermodynamics puts limits on the operation of cyclic devices as expressed by the Kelvin-Planck and Clausius statements. A heat engine cannot operate by exchanging heat with a single heat reservoir, and a refrigerator cannot operate without net work input from an external source. Considering heat engines operating between two fixed temperature reservoirs at TH > T. We draw two conclusions about the thermal efficiency of reversible and irreversible heat engines, known as Carnot Principles. (a) The efficiency of an irreversible heat engine is always less than the efficiency of a reversible one operating between the same two reservoirs. (, ) th th Carnot (b) The efficiencies of all reversible heat engines operating between same two constant temperature heat reservoirs have the same efficiency. Compiled by Yidnekachew M. Page 19 of 23
Figure 5.17 The Carnot principles. As the result of the above, ord Kelvin in 1848 used energy as a thermodynamic property to define temperature and devised a temperature scale that is independent of the thermodynamic substance. He considered the following arrangement: Since the thermal efficiency in general is Q th 1 (5.10) QH For the Carnot Engine, this can be written as gt (, T ) 1 f( T, T ) (5.11) th H H Compiled by Yidnekachew M. Page 20 of 23
Figure 5.18 ord Kelvin's Carnot heat engine arrangement. Considering engines A, B, and C Q Q Q Q (5.12) Q Q 1 1 2 3 2 3 This looks like f( T, T ) f( T, T ) f( T, T ) (5.13) 1 3 1 2 2 3 One way to define the f function is f( T, T ) 1 3 ( T) ( T ) ( T) 1 2 1 (5.14) ( T2) ( T3) ( T3) The simplest form of is the absolute temperature itself. f( T, T ) 1 3 The Carnot thermal efficiency becomes T th, rev 1 TH 1 (5.15) T3 T (5.16) Compiled by Yidnekachew M. Page 21 of 23
This is the maximum possible efficiency of a heat engine operating between two heat reservoirs at temperatures TH and T. Note that the temperatures are absolute temperatures. These statements form the basis for establishing an absolute temperature scale, also called the Kelvin scale, related to the heat transfers between a reversible device and the high- and lowtemperature heat reservoirs by Q Q H T T (5.17) H Then the QH/Q ratio can be replaced by TH/T for reversible devices, where TH and T are the absolute temperatures of the high- and low-temperature heat reservoirs, respectively. This result is only valid for heat exchange across a heat engine operating between two constant temperature heat reservoirs. These results do not apply when the heat exchange is occurring with heat sources and sinks that do not have constant temperature. The thermal efficiencies of actual and reversible heat engines operating between the same temperature limits compare as follows: < th, rev irreversible heat engine th th, rev reversible heat engine th, rev impossible heat engine Reversed Carnot Device Coefficient of Performance If the Carnot device is caused to operate in the reversed cycle, the reversible heat pump is created. The COP of reversible refrigerators and heat pumps are given in a similar manner to that of the Carnot heat engine as COP R T T T H Q Q Q H 1 TH 1 T 1 QH 1 Q (5.18) (5.19) Compiled by Yidnekachew M. Page 22 of 23
and COP H HP TH T T QH Q Q H TH T TH 1 T QH Q QH 1 Q (5.20) (5.21) Again, these are the maximum possible COPs for a refrigerator or a heat pump operating between the temperature limits of TH and T. The coefficients of performance of actual and reversible (such as Carnot) refrigerators operating between the same temperature limits compare as follows: < COPR, rev irreversible refrigerator COPR COPR, rev reversible refrigerator COPR, rev impossible refrigerator A similar relation can be obtained for heat pumps by replacing all values of COPR by COPHP in the above relation. Compiled by Yidnekachew M. Page 23 of 23